Rapid sweep radiating system



HN N

Feb. 24, 1948. c. c. cu'rLER RAPID SWEEP RADIATING SYSTEM Filed sept. z5, 1944 /NVENTR By C C CUYTLER ATTORNEY Patented Feb. 24, 1948 u N 1re D srAfr f PatrieNfrfA o F-Fi CE RAPID SWEEP RADIATING'LSYSTEM Cassius-@.Cntler, Oakhurst, NIJ., assign'or to Bel -i Telephone Laboratories, Incorporated, New* York, N.'Y Y., a"'corporaton off-New'York r- Application .Septemherz 1944, Serial N o. 555,4247

6 Claims;l (Cl. 25m2-11) 1. This invention relatesto ultra-high .frequency radiated transmission. l

An object ofthe'invention is to conveniently and expeditiously change rapidly fromone direction'of transmissionto another or rapidly in' succession from one to another of' a series of directions of transmission.

Let it be assumed that it is desired to sweep over a portion oi the horizon with ultra-high ire-` quency radiation in order to detect anobject, for

example, an iceberg, .and indicate its direction or,

for example, to 'locate andV transmit to a distant..I

receiving station, which upon receivin'g/theradi'- ated energy.. would transmitl backandlthereby...

establish .communication ,or perhaps .would .only

transmit back for the purposeof indicating the.`

direction of the receiving station.

Afurther object of the inventionis to provide a microwave transmission system for. two-.way

communication between two stations constructed in accordance with an embodimentof theinvention and between .one such station and an equivalent station.

A feature of the invention. .comprises theutilization of receiving, detecting and utilizingmeans 25 for ultra-highl frequency waves which performs the dual purpose of checkingthe accuracy-with which the radiated Vwaves Vare transmitted -to-a desired cooperative receiving station and .receiving wave energy sent backin .the `courseof thetwo-way communication..

For these and other. similar. or analogousipurposes the means,.methods and apparatus char acteristic .of embodyingV or operatingin accordance with the present invention -mightbe utilized.

In accordance A-withan embodiment of the invention, there are provided .instrumentalities comprising a main wave guide and a-pluralityf` of branch wave guides located along the maine wave guide-at intervals of.onehalf of the-wave? length measured along .the vmain .wave guide. .r A

rotating. head forms a wave. guide substantially.Y continuous withthemain wave guide and.. in:`

rotating vpresents a series ofl helically arranged*I irises one after another to thebranch wave guides to permit Vthe energyto be transferred-.to these guides in succession.'` Alternate branch wave guides are twisted ninety-degrees in:V opposite directionsso that thepnergy issuingfromftheir. mouths which. are. slightly expandedinto horns.. are identical .in polarization and phasefand thisenergy .is made to impingeupon .a .paraboloid reiiecting surface .which .causes .theradiated en.

ergy to be directed backwardly past the. vv.waveY guide structure into space.

Z. The invention 'will be'more readily understood from-the accompanying drawln'gsin the sole figure vof whichlan embodiment of the invention" is illustrated:diagrammatica1ly.`

In thedrawings certain known. devices are illustrated'in a purely diagrammatic manner; Among these are suitablegeneratingand coupling means for 'producing ultra-high frequency' waves, designated 'by 'rectangle I, which comprise apparatus such .as disclosed in either of the patents to Southworth 2,153,728, Apri1'11, 1939 l or Bowen 2,253,503, August .26, 1941; or its equivaient'. or the' applicationof' Samuel Serial No..

474,122,1i1ed January 30, 1943or equivalent appa'ratus; and the'equipment vdesignated by the apparatus 2,' the .general nature of. which is here after"described', which is similar to that disclosed in thefapplication of Samuel Serial No. 474,122, filed January/'30, 1943',` or its equivalent; andreceiving, detecting land utilizing meansfor u1tra-'. high frequency .waves indicated by therectangle 3 whichis inV accordancefwith the application .of

Friis, SerialNo.v 474,164,'1ed January ,30, 19.43; thedisclosures .of these applications are .incorporated hereinlby reference for all rpurposes and.V to the same extent asthough they were set forth.

in full as a part hereof.vv

TheY apparatus 2 comprises, in general, a receiverdete'cting arrangement and includes a gasiilled tube which'breaks down under .the inureceived from a vdistant ,transmitting .station -or reliectedv from a distantobject andpasses. them o n to the apparatus. y3 by means of which they are detected andindic'ated... As indicatedlin the Samuel application aforesaid .the apparatus 2lin cludesaresonant cavity. .and functions.- asfa gas.v

tube. typeswitch.

Thewave generating and coupling means-I visI associatedwiththe main wave guide lLf'vwhich for. horizontal` sweeping-.may be considered toextend. horizontally, by suitable.V equipmentto cause. the .transmission through.. the guide 4 I of f ultra-high frequency-.waves of. an order of wavelengthfinfreeffspaceof froml 1 centimeter to`r 100 centimeters off. which lcentimetersfmay'be taken as` a typical example.- The upper part Yof Y the .wave guide is .terminated-in. a reecting sur` '1 facet and .containsapl-uralityiofwirises .v5 spaced@ may be coupled to gearing '9 which may be op.

erated by handle lo or other manual or power driven means to rotate the head by remote control. if desired. In rotating the openings flarey brought successively in front of the respective firises to form a continuous opening' directly `from the main wave guide 4 into therespeotive branch wave guides Il so that wave energy of, for example. waves oi type TMO, 1 (circular guide) traversing the main guide is converted into waves of type TED, l (rectangular guide) traversing the branch guides in succession. However, the scone of the invention is not restricted to any particular type or types of waves. Each branch guide, terminates or may terminate in a small radiating horn l2 to cause its energy to iinpinee upon aparaboloid reflecting .surface i3. .The branch guides and the irises 5 are spaced byv about one-half wavelength along the guide and each guide is twisted about Qildegrees. alternate twists beingfin oppositedirections. In this way thewave =energy from successive horns i2 is similar in phase and polarity. The radiating horns reflected therefrom in a slightly different .direc-V tionfrom the energyissuing .from the adjacent radiated horn.v If the horns are lined up in a horizontal direction, the resultant radiation will sweep over an arc in a horizontal direction: if.

the horns l2 are lined up in a vertical direction, the radiation will sweep over a vertical arc and if the horns are arranged in an inclined line, the radiation will sweep over an inclined arc. For the purposes of the following description it will be assumed that the horns are arranged in a horizontal direction. The energy issuing from each horn will be reradiated from the paraboloid surfaccina fairly concentrated beam of greater orflesser dimensions. It may be assumed, for example, that if the energy at the center of the beam is of a definite intensity, the energy in a direction 11/2 degrees fromthis will be reduced in amount by 50 per cent and itmay. therefore, be assumed that the beam is effectively 3 degrees wide. Anyconveni'ent or suitable number of ,radiating horns may be pro-vided. If we assume eight Such horns. a total arc over which theA various lbeams of variation will be transmitted will be approximately 24 degrees wide.

Let it be assumedvthat the rotating head 1 is stopped `for the moment in front of one particular branch wave guideso as to direct radiating energy in a particular direction and that in said direction and lying within the beam is a reflecting object. Some wave energy will be reflecte from the obiect to retraverse the path to the paraboloid surface i3, thence'back to the particular wave guide from which the beam of energy 'is issuing and back to the main wave guide L3.-

Let it be' assumed that trains of ultra-high frequency oscillations, for example, of about 1 microsecond length per train, are being generated at intervals by the apparatus l and transmitted into the main wave guide 4, thenceout through the branch wave guides one after another. After each energy train becomes effective upon the equipment 2, the gas tube comprised within such equipment breaks down and becomes substantially impervious to the passage of ultra-high frequency wave energy, thereby protecting the receiving and detecting equipment 3 from the effects of the relatively powerful transmitted Waves. Upon the cessation of the train of ultra-high frequency waves, the gasfilled tube 2 resumes its normal condition which allows wave energy to be transmitted into the receiving wave vguide I4. When this happens reflected wave energy arriving into the particular branch wave guide l I from which the main wave train was transmitted becomes effective to operate the indicating equipment constituting a part of the devices 3. By rotating the head 'l at intervals by means of the vcrank Hl apparatus rotated, for example, on a ship can sweep over a portion of the horizon with the object of detecting any object, such asan iceberg, periscope or some other vessel the presence of which will be indicated by the indicating equipment of device 3 in a Well-known manner. The devices Smay include, for example, a cathode-ray tube having a. uorescent screen commonly used for detecting and indicating ultra-high frequency radiation. By utilizing the arrangement in the manner described, both the direction and distance of an object may be determined because the initial pulse of the transmitted wave energy will be received in the device 3 to a suicientextent to give an indication on the screen and the time elapsing between this pulse and the return of the reflected wave may be determined in a wellknown manner.v

This equipment may also be used for two-way transmission. Thus, if we assume two stations similar to that described mounted on two ships, each operator may operate his scanning device until his transmitter is directed at the other ship whereupon he will receive an indication that the radiated beam is properly directed. The operator of the other ship will receive this beam on his receiver and upon cessation of transmission by the rst transmitter the receiving transmitter may send out waves in reply. By keying the transmitters in a convenient manner the signals may be transmitted back and forth and each transmitter will have an indication that its outgoing Waves are directed in a proper direction to impinge upon the cooperating receiver on the other ship. The receiving equipment of each station performs the dual purpose of checking upon the proper direction of transmission during the time one transmitter is transmitting and of receiving incoming wave energy from the other transmitter while its local receiver is inactive. Thus, a two-way signaling system is provided in which the stations transmit alternately at suitable intervals. If desired, however, both transmitters may transmit at the same time with the result that both the incoming and outgoing signais will appear upon the receiving screen or be indicated by some suitable indicating device. Inasmuch as the signals arriving from a coop erating transmitter of approximately equal power should and will be considerably greater in amplitude than those due to the reflected waves, there should be no diiculty in interpreting incoming signals during the time outgoing signals are being transmitted. There is thus provided not only a system in which transmission and reception may be carried on alternately but a system in which simultaneous two-way transmission and reception may be carried on and incoming signals delivered to the local transmitter. In the case of simultaneous transmission and reception, it will be obvious that ifa wave train vor a portion of a wave train is received into the' equipment 2 at the precise instant when the tube comprised in that equipment is broken down to prevent passage of wave energy under the received wave guide I4, the received waves will not be indicated. This condition, however, does not prevent successful operation because trains of ultra-high frequency waves of relatively short duration may be transmitted at such successive intervals that the transmission time occupies but a small portion, that is, l per cent or 116 of 1 per cent of the total time, thereby permitting reception during a large part of the total time. If the respective transmitters are so arranged that intervals between wave trains transmitted to them are somewhat dilerent very few trains of waves will be lost. Consequently, if each successive signal, for example, if a total element ofa Morse code is made to consist of a minimum of several successive groups of waves, no more than one group of waves per code element will be lost and successful reception may be accomplished. Thus, for example, if groups of waves are transmitted from one transmitter at intervals 0.01 second, groups of waves from the other transmitter at intervals of .011 second, and if each code element consists of a minimum of twenty-five groups of waves corresponding to approximately one-quarter of a second, it will invariably happen that a considerable number, perhaps twenty or more of each group of waves constituting a code element, will be successfully received. To this end the power supply of the generating oscillator may be keyed on and off in series with a suitable interruptor operating .99. second oi and .01 second on or .989 second on and .011 second ofi as the case may be.

In order to prevent leakage of wave energy through the space between the extension of the main wave guide 4 land the rotating head 'I toroidal slots l5 which are one-quarter wavelength deep may be provided which act as a lter or impedance for filtering out waves tending to leak from one branch wave guide to another or tending to leak into free space instead of being transmitted through the branch wave guides and their respective horns.

What is claimed is:

1. A wave guide having a plurality of irises. supplemental wave guides, movable means for opening the irises in succession to said supplemental wave guides, and phase transforming means in each supplemental guide. 1.1m.

2. A rotating wave guide having a pluralityjof irises, a plurality of branch wave guides, movable means for opening the irises in succession to said branch Wave guides, and means for equalizing the phase'of wave energy issuing from the branch wave guides.

3. Wave guide apparatus comprising a hollow wave guide structure having a plurality of openings arranged longitudinally along the wall thereof, a structure. rotatable with respect thereto having a similar plurality of openings arranged in the wall thereof, and means for driving said structures with respect to one another so as to align said openings in successive pairs, one in each structure.

4. Wave transducing apparatus comprising a main transmission wave guide, branch guides having energy inlet openings, iris means for coupling the openings of said branch guides to said main transmission guide, and wave trap means for reducing cross transfer of energy from one of said openings to another. l.

5. A series of Wave guides, means for supplying an electromagnetic wave of a given frequency and mode to corresponding ends of said guides of said series in a succession of phases progressing serially along the series of guides, radiating structures at the respective other ends of said guides, and polarity transforming means included in the guides whereby waves issuing from the radiating structures are similar in phase an polarity.

6. An electromagnetic wave transducing structure comprising a hollow pipe having a plurality succession.

Y CASSIUS C. CUTLER. 

